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init_1d_model.f90 @ 162

Last change on this file since 162 was 139, checked in by raasch, 17 years ago

New:
---

Plant canopy model of Watanabe (2004,BLM 112,307-341) added.
It can be switched on by the inipar parameter plant_canopy.
The inipar parameter canopy_mode can be used to prescribe a
plant canopy type. The default case is a homogeneous plant
canopy. Heterogeneous distributions of the leaf area
density and the canopy drag coefficient can be defined in the
new routine user_init_plant_canopy (user_interface).
The inipar parameters lad_surface, lad_vertical_gradient and
lad_vertical_gradient_level can be used in order to
prescribe the vertical profile of leaf area density. The
inipar parameter drag_coefficient determines the canopy
drag coefficient.
Finally, the inipar parameter pch_index determines the
index of the upper boundary of the plant canopy.

Allow new case bc_uv_t = 'dirichlet_0' for channel flow.

For unknown variables (CASE DEFAULT) call new subroutine user_data_output_dvrp

Pressure boundary conditions for vertical walls added to the multigrid solver.
They are applied using new wall flag arrays (wall_flags_..) which are defined
for each grid level. New argument gls added to routine user_init_grid
(user_interface).

Frequence of sorting particles can be controlled with new particles_par
parameter dt_sort_particles. Sorting is moved from the SGS timestep loop in
advec_particles after the end of this loop.

advec_particles, check_parameters, data_output_dvrp, header, init_3d_model, init_grid, init_particles, init_pegrid, modules, package_parin, parin, plant_canopy_model, read_var_list, read_3d_binary, user_interface, write_var_list, write_3d_binary

Changed:

Redefine initial nzb_local as the actual total size of topography (later the
extent of topography in nzb_local is reduced by 1dx at the E topography walls
and by 1dy at the N topography walls to form the basis for nzb_s_inner);
for consistency redefine 'single_building' case.

Vertical profiles now based on nzb_s_inner; they are divided by
ngp_2dh_s_inner (scalars, procucts of scalars) and ngp_2dh (staggered velocity
components and their products, procucts of scalars and velocity components),
respectively.

Allow two instead of one digit to specify isosurface and slicer variables.

Status of 3D-volume NetCDF data file only depends on switch netcdf_64bit_3d (check_open)

prognostic_equations include the respective wall_*flux in the parameter list of
calls of diffusion_s. Same as before, only the values of wall_heatflux(0:4)
can be assigned. At present, wall_humidityflux, wall_qflux, wall_salinityflux,
and wall_scalarflux are kept zero. diffusion_s uses the respective wall_*flux
instead of wall_heatflux. This update serves two purposes:

it avoids errors in calculations with humidity/scalar/salinity and prescribed

non-zero wall_heatflux,

it prepares PALM for a possible assignment of wall fluxes of

humidity/scalar/salinity in a future release.

buoyancy, check_open, data_output_dvrp, diffusion_s, diffusivities, flow_statistics, header, init_3d_model, init_dvrp, init_grid, modules, prognostic_equations

Errors:

Bugfix: summation of sums_l_l in diffusivities.

Several bugfixes in the ocean part: Initial density rho is calculated
(init_ocean). Error in initializing u_init and v_init removed
(check_parameters). Calculation of density flux now starts from
nzb+1 (production_e).

Bugfix: pleft/pright changed to pnorth/psouth in sendrecv of particle tail
numbers along y, small bugfixes in the SGS part (advec_particles)

Bugfix: model_string needed a default value (combine_plot_fields)

Bugfix: wavenumber calculation for even nx in routines maketri (poisfft)

Bugfix: assignment of fluxes at walls

Bugfix: absolute value of f must be used when calculating the Blackadar mixing length (init_1d_model)

advec_particles, check_parameters, combine_plot_fields, diffusion_s, diffusivities, init_ocean, init_1d_model, poisfft, production_e

Property svn:keywords set to Id

File size: 33.8 KB

Rev	Line
[1]	1	SUBROUTINE init_1d_model
	2
	3	!------------------------------------------------------------------------------!
	4	! Actual revisions:
	5	! -----------------
[139]	6	!
[1]	7	!
	8	! Former revisions:
	9	! -----------------
[3]	10	! $Id: init_1d_model.f90 139 2007-11-29 09:37:41Z letzel $
[77]	11	!
[139]	12	! 135 2007-11-22 12:24:23Z raasch
	13	! Bugfix: absolute value of f must be used when calculating the Blackadar
	14	! mixing length
	15	!
[83]	16	! 82 2007-04-16 15:40:52Z raasch
	17	! Preprocessor strings for different linux clusters changed to "lc",
	18	! routine local_flush is used for buffer flushing
	19	!
[77]	20	! 75 2007-03-22 09:54:05Z raasch
	21	! Bugfix: preset of tendencies te_em, te_um, te_vm,
	22	! moisture renamed humidity
	23	!
[3]	24	! RCS Log replace by Id keyword, revision history cleaned up
	25	!
[1]	26	! Revision 1.21 2006/06/02 15:19:57 raasch
	27	! cpp-directives extended for lctit
	28	!
	29	! Revision 1.1 1998/03/09 16:22:10 raasch
	30	! Initial revision
	31	!
	32	!
	33	! Description:
	34	! ------------
	35	! 1D-model to initialize the 3D-arrays.
	36	! The temperature profile is set as steady and a corresponding steady solution
	37	! of the wind profile is being computed.
	38	! All subroutines required can be found within this file.
	39	!------------------------------------------------------------------------------!
	40
	41	USE arrays_3d
	42	USE indices
	43	USE model_1d
	44	USE control_parameters
	45
	46	IMPLICIT NONE
	47
	48	CHARACTER (LEN=9) :: time_to_string
	49	INTEGER :: k
	50	REAL :: lambda
	51
	52	!
	53	!-- Allocate required 1D-arrays
	54	ALLOCATE( e1d(nzb:nzt+1), e1d_m(nzb:nzt+1), e1d_p(nzb:nzt+1), &
	55	kh1d(nzb:nzt+1), kh1d_m(nzb:nzt+1), km1d(nzb:nzt+1), &
	56	km1d_m(nzb:nzt+1), l_black(nzb:nzt+1), l1d(nzb:nzt+1), &
	57	l1d_m(nzb:nzt+1), rif1d(nzb:nzt+1), te_e(nzb:nzt+1), &
	58	te_em(nzb:nzt+1), te_u(nzb:nzt+1), te_um(nzb:nzt+1), &
	59	te_v(nzb:nzt+1), te_vm(nzb:nzt+1), u1d(nzb:nzt+1), &
	60	u1d_m(nzb:nzt+1), u1d_p(nzb:nzt+1), v1d(nzb:nzt+1), &
	61	v1d_m(nzb:nzt+1), v1d_p(nzb:nzt+1) )
	62
	63	!
	64	!-- Initialize arrays
	65	IF ( constant_diffusion ) THEN
	66	km1d = km_constant
	67	km1d_m = km_constant
	68	kh1d = km_constant / prandtl_number
	69	kh1d_m = km_constant / prandtl_number
	70	ELSE
	71	e1d = 0.0; e1d_m = 0.0; e1d_p = 0.0
	72	kh1d = 0.0; kh1d_m = 0.0; km1d = 0.0; km1d_m = 0.0
	73	rif1d = 0.0
	74	!
	75	!-- Compute the mixing length
	76	l_black(nzb) = 0.0
	77
	78	IF ( TRIM( mixing_length_1d ) == 'blackadar' ) THEN
	79	!
	80	!-- Blackadar mixing length
	81	IF ( f /= 0.0 ) THEN
[135]	82	lambda = 2.7E-4 * SQRT( ug(nzt+1)2 + vg(nzt+1)2 ) / &
	83	ABS( f ) + 1E-10
[1]	84	ELSE
	85	lambda = 30.0
	86	ENDIF
	87
	88	DO k = nzb+1, nzt+1
	89	l_black(k) = kappa * zu(k) / ( 1.0 + kappa * zu(k) / lambda )
	90	ENDDO
	91
	92	ELSEIF ( TRIM( mixing_length_1d ) == 'as_in_3d_model' ) THEN
	93	!
	94	!-- Use the same mixing length as in 3D model
	95	l_black(1:nzt) = l_grid
	96	l_black(nzt+1) = l_black(nzt)
	97
	98	ENDIF
	99
	100	!
	101	!-- Adjust mixing length to the prandtl mixing length (within the prandtl
	102	!-- layer)
	103	IF ( adjust_mixing_length .AND. prandtl_layer ) THEN
	104	k = nzb+1
	105	l_black(k) = MIN( l_black(k), kappa * zu(k) )
	106	ENDIF
	107	ENDIF
	108	l1d = l_black
	109	l1d_m = l_black
	110	u1d = u_init
	111	u1d_m = u_init
	112	u1d_p = u_init
	113	v1d = v_init
	114	v1d_m = v_init
	115	v1d_p = v_init
	116
	117	!
	118	!-- Set initial horizontal velocities at the lowest grid levels to a very small
	119	!-- value in order to avoid too small time steps caused by the diffusion limit
	120	!-- in the initial phase of a run (at k=1, dz/2 occurs in the limiting formula!)
	121	u1d(0:1) = 0.1
	122	u1d_m(0:1) = 0.1
	123	u1d_p(0:1) = 0.1
	124	v1d(0:1) = 0.1
	125	v1d_m(0:1) = 0.1
	126	v1d_p(0:1) = 0.1
	127
	128	!
	129	!-- For u, theta and the momentum fluxes plausible values are set
	130	IF ( prandtl_layer ) THEN
	131	us1d = 0.1 ! without initial friction the flow would not change
	132	ELSE
	133	e1d(nzb+1) = 1.0
	134	km1d(nzb+1) = 1.0
	135	us1d = 0.0
	136	ENDIF
	137	ts1d = 0.0
	138	usws1d = 0.0; usws1d_m = 0.0
	139	vsws1d = 0.0; vsws1d_m = 0.0
	140	z01d = roughness_length
[75]	141	IF ( humidity .OR. passive_scalar ) qs1d = 0.0
[1]	142
	143	!
[46]	144	!-- Tendencies must be preset in order to avoid runtime errors within the
	145	!-- first Runge-Kutta step
	146	te_em = 0.0
	147	te_um = 0.0
	148	te_vm = 0.0
	149
	150	!
[1]	151	!-- Set start time in hh:mm:ss - format
	152	simulated_time_chr = time_to_string( simulated_time_1d )
	153
	154	!
	155	!-- Integrate the 1D-model equations using the leap-frog scheme
	156	CALL time_integration_1d
	157
	158
	159	END SUBROUTINE init_1d_model
	160
	161
	162
	163	SUBROUTINE time_integration_1d
	164
	165	!------------------------------------------------------------------------------!
	166	! Description:
	167	! ------------
	168	! Leap-frog time differencing scheme for the 1D-model.
	169	!------------------------------------------------------------------------------!
	170
	171	USE arrays_3d
	172	USE control_parameters
	173	USE indices
	174	USE model_1d
	175	USE pegrid
	176
	177	IMPLICIT NONE
	178
	179	CHARACTER (LEN=9) :: time_to_string
	180	INTEGER :: k
	181	REAL :: a, b, dissipation, dpt_dz, flux, kmzm, kmzp, l_stable, pt_0, &
	182	uv_total
	183
	184	!
	185	!-- Determine the time step at the start of a 1D-simulation and
	186	!-- determine and printout quantities used for run control
	187	CALL timestep_1d
	188	CALL run_control_1d
	189
	190	!
	191	!-- Start of time loop
	192	DO WHILE ( simulated_time_1d < end_time_1d .AND. .NOT. stop_dt_1d )
	193
	194	!
	195	!-- Depending on the timestep scheme, carry out one or more intermediate
	196	!-- timesteps
	197
	198	intermediate_timestep_count = 0
	199	DO WHILE ( intermediate_timestep_count < &
	200	intermediate_timestep_count_max )
	201
	202	intermediate_timestep_count = intermediate_timestep_count + 1
	203
	204	CALL timestep_scheme_steering
	205
	206	!
	207	!-- Compute all tendency terms. If a Prandtl-layer is simulated, k starts
	208	!-- at nzb+2.
	209	DO k = nzb_diff, nzt
	210
	211	kmzm = 0.5 * ( km1d_m(k-1) + km1d_m(k) )
	212	kmzp = 0.5 * ( km1d_m(k) + km1d_m(k+1) )
	213	!
	214	!-- u-component
	215	te_u(k) = f * ( v1d(k) - vg(k) ) + ( &
	216	kmzp * ( u1d_m(k+1) - u1d_m(k) ) * ddzu(k+1) &
	217	- kmzm * ( u1d_m(k) - u1d_m(k-1) ) * ddzu(k) &
	218	) * ddzw(k)
	219	!
	220	!-- v-component
	221	te_v(k) = -f * ( u1d(k) - ug(k) ) + ( &
	222	kmzp * ( v1d_m(k+1) - v1d_m(k) ) * ddzu(k+1) &
	223	- kmzm * ( v1d_m(k) - v1d_m(k-1) ) * ddzu(k) &
	224	) * ddzw(k)
	225	ENDDO
	226	IF ( .NOT. constant_diffusion ) THEN
	227	DO k = nzb_diff, nzt
	228	!
	229	!-- TKE
	230	kmzm = 0.5 * ( km1d_m(k-1) + km1d_m(k) )
	231	kmzp = 0.5 * ( km1d_m(k) + km1d_m(k+1) )
[75]	232	IF ( .NOT. humidity ) THEN
[1]	233	pt_0 = pt_init(k)
	234	flux = ( pt_init(k+1)-pt_init(k-1) ) * dd2zu(k)
	235	ELSE
	236	pt_0 = pt_init(k) * ( 1.0 + 0.61 * q_init(k) )
	237	flux = ( ( pt_init(k+1) - pt_init(k-1) ) + &
	238	0.61 * pt_init(k) * ( q_init(k+1) - q_init(k-1) ) &
	239	) * dd2zu(k)
	240	ENDIF
	241
	242	IF ( dissipation_1d == 'detering' ) THEN
	243	!
	244	!-- According to Detering, c_e=0.064
	245	dissipation = 0.064 * e1d_m(k) * SQRT( e1d_m(k) ) / l1d_m(k)
	246	ELSEIF ( dissipation_1d == 'as_in_3d_model' ) THEN
	247	dissipation = ( 0.19 + 0.74 * l1d_m(k) / l_grid(k) ) &
	248	* e1d_m(k) * SQRT( e1d_m(k) ) / l1d_m(k)
	249	ENDIF
	250
	251	te_e(k) = km1d(k) * ( ( ( u1d(k+1) - u1d(k-1) ) * dd2zu(k) )**2&
	252	+ ( ( v1d(k+1) - v1d(k-1) ) * dd2zu(k) )**2&
	253	) &
	254	- g / pt_0 * kh1d(k) * flux &
	255	+ ( &
	256	kmzp * ( e1d_m(k+1) - e1d_m(k) ) * ddzu(k+1) &
	257	- kmzm * ( e1d_m(k) - e1d_m(k-1) ) * ddzu(k) &
	258	) * ddzw(k) &
	259	- dissipation
	260	ENDDO
	261	ENDIF
	262
	263	!
	264	!-- Tendency terms at the top of the Prandtl-layer.
	265	!-- Finite differences of the momentum fluxes are computed using half the
	266	!-- normal grid length (2.0*ddzw(k)) for the sake of enhanced accuracy
	267	IF ( prandtl_layer ) THEN
	268
	269	k = nzb+1
	270	kmzm = 0.5 * ( km1d_m(k-1) + km1d_m(k) )
	271	kmzp = 0.5 * ( km1d_m(k) + km1d_m(k+1) )
[75]	272	IF ( .NOT. humidity ) THEN
[1]	273	pt_0 = pt_init(k)
	274	flux = ( pt_init(k+1)-pt_init(k-1) ) * dd2zu(k)
	275	ELSE
	276	pt_0 = pt_init(k) * ( 1.0 + 0.61 * q_init(k) )
	277	flux = ( ( pt_init(k+1) - pt_init(k-1) ) + &
	278	0.61 * pt_init(k) * ( q_init(k+1) - q_init(k-1) ) &
	279	) * dd2zu(k)
	280	ENDIF
	281
	282	IF ( dissipation_1d == 'detering' ) THEN
	283	!
	284	!-- According to Detering, c_e=0.064
	285	dissipation = 0.064 * e1d_m(k) * SQRT( e1d_m(k) ) / l1d_m(k)
	286	ELSEIF ( dissipation_1d == 'as_in_3d_model' ) THEN
	287	dissipation = ( 0.19 + 0.74 * l1d_m(k) / l_grid(k) ) &
	288	* e1d_m(k) * SQRT( e1d_m(k) ) / l1d_m(k)
	289	ENDIF
	290
	291	!
	292	!-- u-component
	293	te_u(k) = f * ( v1d(k) - vg(k) ) + ( &
	294	kmzp * ( u1d_m(k+1) - u1d_m(k) ) * ddzu(k+1) + usws1d_m &
	295	) * 2.0 * ddzw(k)
	296	!
	297	!-- v-component
	298	te_v(k) = -f * ( u1d(k) - ug(k) ) + ( &
	299	kmzp * ( v1d_m(k+1) - v1d_m(k) ) * ddzu(k+1) + vsws1d_m &
	300	) * 2.0 * ddzw(k)
	301	!
	302	!-- TKE
	303	te_e(k) = km1d(k) * ( ( ( u1d(k+1) - u1d(k-1) ) * dd2zu(k) )**2 &
	304	+ ( ( v1d(k+1) - v1d(k-1) ) * dd2zu(k) )**2 &
	305	) &
	306	- g / pt_0 * kh1d(k) * flux &
	307	+ ( &
	308	kmzp * ( e1d_m(k+1) - e1d_m(k) ) * ddzu(k+1) &
	309	- kmzm * ( e1d_m(k) - e1d_m(k-1) ) * ddzu(k) &
	310	) * ddzw(k) &
	311	- dissipation
	312	ENDIF
	313
	314	!
	315	!-- Prognostic equations for all 1D variables
	316	DO k = nzb+1, nzt
	317
	318	u1d_p(k) = ( 1. - tsc(1) ) * u1d_m(k) + &
	319	tsc(1) * u1d(k) + dt_1d * ( tsc(2) * te_u(k) + &
	320	tsc(3) * te_um(k) )
	321	v1d_p(k) = ( 1. - tsc(1) ) * v1d_m(k) + &
	322	tsc(1) * v1d(k) + dt_1d * ( tsc(2) * te_v(k) + &
	323	tsc(3) * te_vm(k) )
	324
	325	ENDDO
	326	IF ( .NOT. constant_diffusion ) THEN
	327	DO k = nzb+1, nzt
	328
	329	e1d_p(k) = ( 1. - tsc(1) ) * e1d_m(k) + &
	330	tsc(1) * e1d(k) + dt_1d * ( tsc(2) * te_e(k) + &
	331	tsc(3) * te_em(k) )
	332
	333	ENDDO
	334	!
	335	!-- Eliminate negative TKE values, which can result from the
	336	!-- integration due to numerical inaccuracies. In such cases the TKE
	337	!-- value is reduced to 10 percent of its old value.
	338	WHERE ( e1d_p < 0.0 ) e1d_p = 0.1 * e1d
	339	ENDIF
	340
	341	!
	342	!-- Calculate tendencies for the next Runge-Kutta step
	343	IF ( timestep_scheme(1:5) == 'runge' ) THEN
	344	IF ( intermediate_timestep_count == 1 ) THEN
	345
	346	DO k = nzb+1, nzt
	347	te_um(k) = te_u(k)
	348	te_vm(k) = te_v(k)
	349	ENDDO
	350
	351	IF ( .NOT. constant_diffusion ) THEN
	352	DO k = nzb+1, nzt
	353	te_em(k) = te_e(k)
	354	ENDDO
	355	ENDIF
	356
	357	ELSEIF ( intermediate_timestep_count < &
	358	intermediate_timestep_count_max ) THEN
	359
	360	DO k = nzb+1, nzt
	361	te_um(k) = -9.5625 * te_u(k) + 5.3125 * te_um(k)
	362	te_vm(k) = -9.5625 * te_v(k) + 5.3125 * te_vm(k)
	363	ENDDO
	364
	365	IF ( .NOT. constant_diffusion ) THEN
	366	DO k = nzb+1, nzt
	367	te_em(k) = -9.5625 * te_e(k) + 5.3125 * te_em(k)
	368	ENDDO
	369	ENDIF
	370
	371	ENDIF
	372	ENDIF
	373
	374
	375	!
	376	!-- Boundary conditions for the prognostic variables.
	377	!-- At the top boundary (nzt+1) u,v and e keep their initial values
	378	!-- (ug(nzt+1), vg(nzt+1), 0), at the bottom boundary the mirror
	379	!-- boundary condition applies to u and v.
	380	!-- The boundary condition for e is set further below ( (u/cm)*2 ).
	381	u1d_p(nzb) = -u1d_p(nzb+1)
	382	v1d_p(nzb) = -v1d_p(nzb+1)
	383
	384	!
	385	!-- If necessary, apply the time filter
	386	IF ( asselin_filter_factor /= 0.0 .AND. &
	387	timestep_scheme(1:5) /= 'runge' ) THEN
	388
	389	u1d = u1d + asselin_filter_factor * ( u1d_p - 2.0 * u1d + u1d_m )
	390	v1d = v1d + asselin_filter_factor * ( v1d_p - 2.0 * v1d + v1d_m )
	391
	392	IF ( .NOT. constant_diffusion ) THEN
	393	e1d = e1d + asselin_filter_factor * &
	394	( e1d_p - 2.0 * e1d + e1d_m )
	395	ENDIF
	396
	397	ENDIF
	398
	399	!
	400	!-- Swap the time levels in preparation for the next time step.
	401	IF ( timestep_scheme(1:4) == 'leap' ) THEN
	402	u1d_m = u1d
	403	v1d_m = v1d
	404	IF ( .NOT. constant_diffusion ) THEN
	405	e1d_m = e1d
	406	kh1d_m = kh1d ! The old diffusion quantities are required for
	407	km1d_m = km1d ! explicit diffusion in the leap-frog scheme.
	408	l1d_m = l1d
	409	IF ( prandtl_layer ) THEN
	410	usws1d_m = usws1d
	411	vsws1d_m = vsws1d
	412	ENDIF
	413	ENDIF
	414	ENDIF
	415	u1d = u1d_p
	416	v1d = v1d_p
	417	IF ( .NOT. constant_diffusion ) THEN
	418	e1d = e1d_p
	419	ENDIF
	420
	421	!
	422	!-- Compute diffusion quantities
	423	IF ( .NOT. constant_diffusion ) THEN
	424
	425	!
	426	!-- First compute the vertical fluxes in the Prandtl-layer
	427	IF ( prandtl_layer ) THEN
	428	!
	429	!-- Compute theta* using Rif numbers of the previous time step
	430	IF ( rif1d(1) >= 0.0 ) THEN
	431	!
	432	!-- Stable stratification
	433	ts1d = kappa * ( pt_init(nzb+1) - pt_init(nzb) ) / &
	434	( LOG( zu(nzb+1) / z01d ) + 5.0 * rif1d(nzb+1) * &
	435	( zu(nzb+1) - z01d ) / zu(nzb+1) &
	436	)
	437	ELSE
	438	!
	439	!-- Unstable stratification
	440	a = SQRT( 1.0 - 16.0 * rif1d(nzb+1) )
	441	b = SQRT( 1.0 - 16.0 * rif1d(nzb+1) / zu(nzb+1) * z01d )
	442	!
	443	!-- In the borderline case the formula for stable stratification
	444	!-- must be applied, because otherwise a zero division would
	445	!-- occur in the argument of the logarithm.
	446	IF ( a == 0.0 .OR. b == 0.0 ) THEN
	447	ts1d = kappa * ( pt_init(nzb+1) - pt_init(nzb) ) / &
	448	( LOG( zu(nzb+1) / z01d ) + 5.0 * rif1d(nzb+1) * &
	449	( zu(nzb+1) - z01d ) / zu(nzb+1) &
	450	)
	451	ELSE
	452	ts1d = kappa * ( pt_init(nzb+1) - pt_init(nzb) ) / &
	453	LOG( (a-1.0) / (a+1.0) * (b+1.0) / (b-1.0) )
	454	ENDIF
	455	ENDIF
	456
	457	ENDIF ! prandtl_layer
	458
	459	!
	460	!-- Compute the Richardson-flux numbers,
	461	!-- first at the top of the Prandtl-layer using u* of the previous
	462	!-- time step (+1E-30, if u* = 0), then in the remaining area. There
	463	!-- the rif-numbers of the previous time step are used.
	464
	465	IF ( prandtl_layer ) THEN
[75]	466	IF ( .NOT. humidity ) THEN
[1]	467	pt_0 = pt_init(nzb+1)
	468	flux = ts1d
	469	ELSE
	470	pt_0 = pt_init(nzb+1) * ( 1.0 + 0.61 * q_init(nzb+1) )
	471	flux = ts1d + 0.61 * pt_init(k) * qs1d
	472	ENDIF
	473	rif1d(nzb+1) = zu(nzb+1) * kappa * g * flux / &
	474	( pt_0 * ( us1d**2 + 1E-30 ) )
	475	ENDIF
	476
	477	DO k = nzb_diff, nzt
[75]	478	IF ( .NOT. humidity ) THEN
[1]	479	pt_0 = pt_init(k)
	480	flux = ( pt_init(k+1) - pt_init(k-1) ) * dd2zu(k)
	481	ELSE
	482	pt_0 = pt_init(k) * ( 1.0 + 0.61 * q_init(k) )
	483	flux = ( ( pt_init(k+1) - pt_init(k-1) ) &
	484	+ 0.61 * pt_init(k) * ( q_init(k+1) - q_init(k-1) )&
	485	) * dd2zu(k)
	486	ENDIF
	487	IF ( rif1d(k) >= 0.0 ) THEN
	488	rif1d(k) = g / pt_0 * flux / &
	489	( ( ( u1d(k+1) - u1d(k-1) ) * dd2zu(k) )**2 &
	490	+ ( ( v1d(k+1) - v1d(k-1) ) * dd2zu(k) )**2 &
	491	+ 1E-30 &
	492	)
	493	ELSE
	494	rif1d(k) = g / pt_0 * flux / &
	495	( ( ( u1d(k+1) - u1d(k-1) ) * dd2zu(k) )**2 &
	496	+ ( ( v1d(k+1) - v1d(k-1) ) * dd2zu(k) )**2 &
	497	+ 1E-30 &
	498	) * ( 1.0 - 16.0 * rif1d(k) )**0.25
	499	ENDIF
	500	ENDDO
	501	!
	502	!-- Richardson-numbers must remain restricted to a realistic value
	503	!-- range. It is exceeded excessively for very small velocities
	504	!-- (u,v --> 0).
	505	WHERE ( rif1d < rif_min ) rif1d = rif_min
	506	WHERE ( rif1d > rif_max ) rif1d = rif_max
	507
	508	!
	509	!-- Compute u* from the absolute velocity value
	510	IF ( prandtl_layer ) THEN
	511	uv_total = SQRT( u1d(nzb+1)2 + v1d(nzb+1)2 )
	512
	513	IF ( rif1d(nzb+1) >= 0.0 ) THEN
	514	!
	515	!-- Stable stratification
	516	us1d = kappa * uv_total / ( &
	517	LOG( zu(nzb+1) / z01d ) + 5.0 * rif1d(nzb+1) * &
	518	( zu(nzb+1) - z01d ) / zu(nzb+1) &
	519	)
	520	ELSE
	521	!
	522	!-- Unstable stratification
	523	a = 1.0 / SQRT( SQRT( 1.0 - 16.0 * rif1d(nzb+1) ) )
	524	b = 1.0 / SQRT( SQRT( 1.0 - 16.0 * rif1d(nzb+1) / zu(nzb+1) &
	525	* z01d ) )
	526	!
	527	!-- In the borderline case the formula for stable stratification
	528	!-- must be applied, because otherwise a zero division would
	529	!-- occur in the argument of the logarithm.
	530	IF ( a == 1.0 .OR. b == 1.0 ) THEN
	531	us1d = kappa * uv_total / ( &
	532	LOG( zu(nzb+1) / z01d ) + &
	533	5.0 * rif1d(nzb+1) * ( zu(nzb+1) - z01d ) / &
	534	zu(nzb+1) )
	535	ELSE
	536	us1d = kappa * uv_total / ( &
	537	LOG( (1.0+b) / (1.0-b) * (1.0-a) / (1.0+a) ) +&
	538	2.0 * ( ATAN( b ) - ATAN( a ) ) &
	539	)
	540	ENDIF
	541	ENDIF
	542
	543	!
	544	!-- Compute the momentum fluxes for the diffusion terms
	545	usws1d = - u1d(nzb+1) / uv_total * us1d**2
	546	vsws1d = - v1d(nzb+1) / uv_total * us1d**2
	547
	548	!
	549	!-- Boundary condition for the turbulent kinetic energy at the top
	550	!-- of the Prandtl-layer. c_m = 0.4 according to Detering.
	551	!-- Additional Neumann condition de/dz = 0 at nzb is set to ensure
	552	!-- compatibility with the 3D model.
	553	IF ( ibc_e_b == 2 ) THEN
	554	e1d(nzb+1) = ( us1d / 0.1 )**2
	555	! e1d(nzb+1) = ( us1d / 0.4 )**2 !not used so far, see also
	556	!prandtl_fluxes
	557	ENDIF
	558	e1d(nzb) = e1d(nzb+1)
	559
[75]	560	IF ( humidity .OR. passive_scalar ) THEN
[1]	561	!
	562	!-- Compute q*
	563	IF ( rif1d(1) >= 0.0 ) THEN
	564	!
	565	!-- Stable stratification
	566	qs1d = kappa * ( q_init(nzb+1) - q_init(nzb) ) / &
	567	( LOG( zu(nzb+1) / z01d ) + 5.0 * rif1d(nzb+1) * &
	568	( zu(nzb+1) - z01d ) / zu(nzb+1) &
	569	)
	570	ELSE
	571	!
	572	!-- Unstable stratification
	573	a = SQRT( 1.0 - 16.0 * rif1d(nzb+1) )
	574	b = SQRT( 1.0 - 16.0 * rif1d(nzb+1) / zu(nzb+1) * z01d )
	575	!
	576	!-- In the borderline case the formula for stable stratification
	577	!-- must be applied, because otherwise a zero division would
	578	!-- occur in the argument of the logarithm.
	579	IF ( a == 1.0 .OR. b == 1.0 ) THEN
	580	qs1d = kappa * ( q_init(nzb+1) - q_init(nzb) ) / &
	581	( LOG( zu(nzb+1) / z01d ) + 5.0 * rif1d(nzb+1) * &
	582	( zu(nzb+1) - z01d ) / zu(nzb+1) &
	583	)
	584	ELSE
	585	qs1d = kappa * ( q_init(nzb+1) - q_init(nzb) ) / &
	586	LOG( (a-1.0) / (a+1.0) * (b+1.0) / (b-1.0) )
	587	ENDIF
	588	ENDIF
	589	ELSE
	590	qs1d = 0.0
	591	ENDIF
	592
	593	ENDIF ! prandtl_layer
	594
	595	!
	596	!-- Compute the diabatic mixing length
	597	IF ( mixing_length_1d == 'blackadar' ) THEN
	598	DO k = nzb+1, nzt
	599	IF ( rif1d(k) >= 0.0 ) THEN
	600	l1d(k) = l_black(k) / ( 1.0 + 5.0 * rif1d(k) )
	601	ELSE
	602	l1d(k) = l_black(k) * ( 1.0 - 16.0 * rif1d(k) )**0.25
	603	ENDIF
	604	l1d(k) = l_black(k)
	605	ENDDO
	606
	607	ELSEIF ( mixing_length_1d == 'as_in_3d_model' ) THEN
	608	DO k = nzb+1, nzt
	609	dpt_dz = ( pt_init(k+1) - pt_init(k-1) ) * dd2zu(k)
	610	IF ( dpt_dz > 0.0 ) THEN
	611	l_stable = 0.76 * SQRT( e1d(k) ) / &
	612	SQRT( g / pt_init(k) * dpt_dz ) + 1E-5
	613	ELSE
	614	l_stable = l_grid(k)
	615	ENDIF
	616	l1d(k) = MIN( l_grid(k), l_stable )
	617	ENDDO
	618	ENDIF
	619
	620	!
	621	!-- Adjust mixing length to the prandtl mixing length
	622	IF ( adjust_mixing_length .AND. prandtl_layer ) THEN
	623	k = nzb+1
	624	IF ( rif1d(k) >= 0.0 ) THEN
	625	l1d(k) = MIN( l1d(k), kappa * zu(k) / ( 1.0 + 5.0 * &
	626	rif1d(k) ) )
	627	ELSE
	628	l1d(k) = MIN( l1d(k), kappa * zu(k) * &
	629	SQRT( SQRT( 1.0 - 16.0 * rif1d(k) ) ) )
	630	ENDIF
	631	ENDIF
	632
	633	!
	634	!-- Compute the diffusion coefficients for momentum via the
	635	!-- corresponding Prandtl-layer relationship and according to
	636	!-- Prandtl-Kolmogorov, respectively. The unstable stratification is
	637	!-- computed via the adiabatic mixing length, for the unstability has
	638	!-- already been taken account of via the TKE (cf. also Diss.).
	639	IF ( prandtl_layer ) THEN
	640	IF ( rif1d(nzb+1) >= 0.0 ) THEN
	641	km1d(nzb+1) = us1d * kappa * zu(nzb+1) / &
	642	( 1.0 + 5.0 * rif1d(nzb+1) )
	643	ELSE
	644	km1d(nzb+1) = us1d * kappa * zu(nzb+1) * &
	645	( 1.0 - 16.0 * rif1d(nzb+1) )**0.25
	646	ENDIF
	647	ENDIF
	648	DO k = nzb_diff, nzt
	649	! km1d(k) = 0.4 * SQRT( e1d(k) ) !changed: adjustment to 3D-model
	650	km1d(k) = 0.1 * SQRT( e1d(k) )
	651	IF ( rif1d(k) >= 0.0 ) THEN
	652	km1d(k) = km1d(k) * l1d(k)
	653	ELSE
	654	km1d(k) = km1d(k) * l_black(k)
	655	ENDIF
	656	ENDDO
	657
	658	!
	659	!-- Add damping layer
	660	DO k = damp_level_ind_1d+1, nzt+1
	661	km1d(k) = 1.1 * km1d(k-1)
	662	km1d(k) = MIN( km1d(k), 10.0 )
	663	ENDDO
	664
	665	!
	666	!-- Compute the diffusion coefficient for heat via the relationship
	667	!-- kh = phim / phih * km
	668	DO k = nzb+1, nzt
	669	IF ( rif1d(k) >= 0.0 ) THEN
	670	kh1d(k) = km1d(k)
	671	ELSE
	672	kh1d(k) = km1d(k) * ( 1.0 - 16.0 * rif1d(k) )**0.25
	673	ENDIF
	674	ENDDO
	675
	676	ENDIF ! .NOT. constant_diffusion
	677
	678	!
	679	!-- The Runge-Kutta scheme needs the recent diffusion quantities
	680	IF ( timestep_scheme(1:5) == 'runge' ) THEN
	681	u1d_m = u1d
	682	v1d_m = v1d
	683	IF ( .NOT. constant_diffusion ) THEN
	684	e1d_m = e1d
	685	kh1d_m = kh1d
	686	km1d_m = km1d
	687	l1d_m = l1d
	688	IF ( prandtl_layer ) THEN
	689	usws1d_m = usws1d
	690	vsws1d_m = vsws1d
	691	ENDIF
	692	ENDIF
	693	ENDIF
	694
	695
	696	ENDDO ! intermediate step loop
	697
	698	!
	699	!-- Increment simulated time and output times
	700	current_timestep_number_1d = current_timestep_number_1d + 1
	701	simulated_time_1d = simulated_time_1d + dt_1d
	702	simulated_time_chr = time_to_string( simulated_time_1d )
	703	time_pr_1d = time_pr_1d + dt_1d
	704	time_run_control_1d = time_run_control_1d + dt_1d
	705
	706	!
	707	!-- Determine and print out quantities for run control
	708	IF ( time_run_control_1d >= dt_run_control_1d ) THEN
	709	CALL run_control_1d
	710	time_run_control_1d = time_run_control_1d - dt_run_control_1d
	711	ENDIF
	712
	713	!
	714	!-- Profile output on file
	715	IF ( time_pr_1d >= dt_pr_1d ) THEN
	716	CALL print_1d_model
	717	time_pr_1d = time_pr_1d - dt_pr_1d
	718	ENDIF
	719
	720	!
	721	!-- Determine size of next time step
	722	CALL timestep_1d
	723
	724	ENDDO ! time loop
	725
	726
	727	END SUBROUTINE time_integration_1d
	728
	729
	730	SUBROUTINE run_control_1d
	731
	732	!------------------------------------------------------------------------------!
	733	! Description:
	734	! ------------
	735	! Compute and print out quantities for run control of the 1D model.
	736	!------------------------------------------------------------------------------!
	737
	738	USE constants
	739	USE indices
	740	USE model_1d
	741	USE pegrid
	742	USE control_parameters
	743
	744	IMPLICIT NONE
	745
	746	INTEGER :: k
	747	REAL :: alpha, energy, umax, uv_total, vmax
	748
	749	!
	750	!-- Output
	751	IF ( myid == 0 ) THEN
	752	!
	753	!-- If necessary, write header
	754	IF ( .NOT. run_control_header_1d ) THEN
	755	WRITE ( 15, 100 )
	756	run_control_header_1d = .TRUE.
	757	ENDIF
	758
	759	!
	760	!-- Compute control quantities
	761	!-- grid level nzp is excluded due to mirror boundary condition
	762	umax = 0.0; vmax = 0.0; energy = 0.0
	763	DO k = nzb+1, nzt+1
	764	umax = MAX( ABS( umax ), ABS( u1d(k) ) )
	765	vmax = MAX( ABS( vmax ), ABS( v1d(k) ) )
	766	energy = energy + 0.5 * ( u1d(k)2 + v1d(k)2 )
	767	ENDDO
	768	energy = energy / REAL( nzt - nzb + 1 )
	769
	770	uv_total = SQRT( u1d(nzb+1)2 + v1d(nzb+1)2 )
	771	IF ( ABS( v1d(nzb+1) ) .LT. 1.0E-5 ) THEN
	772	alpha = ACOS( SIGN( 1.0 , u1d(nzb+1) ) )
	773	ELSE
	774	alpha = ACOS( u1d(nzb+1) / uv_total )
	775	IF ( v1d(nzb+1) <= 0.0 ) alpha = 2.0 * pi - alpha
	776	ENDIF
	777	alpha = alpha / ( 2.0 * pi ) * 360.0
	778
	779	WRITE ( 15, 101 ) current_timestep_number_1d, simulated_time_chr, &
	780	dt_1d, umax, vmax, us1d, alpha, energy
	781	!
	782	!-- Write buffer contents to disc immediately
[82]	783	CALL local_flush( 15 )
[1]	784
	785	ENDIF
	786
	787	!
	788	!-- formats
	789	100 FORMAT (///'1D-Zeitschrittkontrollausgaben:'/ &
	790	&'------------------------------'// &
	791	&'ITER. HH:MM:SS DT UMAX VMAX U* ALPHA ENERG.'/ &
	792	&'-------------------------------------------------------------')
	793	101 FORMAT (I5,2X,A9,1X,F6.2,2X,F6.2,1X,F6.2,2X,F5.3,2X,F5.1,2X,F7.2)
	794
	795
	796	END SUBROUTINE run_control_1d
	797
	798
	799
	800	SUBROUTINE timestep_1d
	801
	802	!------------------------------------------------------------------------------!
	803	! Description:
	804	! ------------
	805	! Compute the time step w.r.t. the diffusion criterion
	806	!------------------------------------------------------------------------------!
	807
	808	USE arrays_3d
	809	USE indices
	810	USE model_1d
	811	USE pegrid
	812	USE control_parameters
	813
	814	IMPLICIT NONE
	815
	816	INTEGER :: k
	817	REAL :: div, dt_diff, fac, percent_change, value
	818
	819
	820	!
	821	!-- Compute the currently feasible time step according to the diffusion
	822	!-- criterion. At nzb+1 the half grid length is used.
	823	IF ( timestep_scheme(1:4) == 'leap' ) THEN
	824	fac = 0.25
	825	ELSE
	826	fac = 0.35
	827	ENDIF
	828	dt_diff = dt_max_1d
	829	DO k = nzb+2, nzt
	830	value = fac * dzu(k) * dzu(k) / ( km1d(k) + 1E-20 )
	831	dt_diff = MIN( value, dt_diff )
	832	ENDDO
	833	value = fac * zu(nzb+1) * zu(nzb+1) / ( km1d(nzb+1) + 1E-20 )
	834	dt_1d = MIN( value, dt_diff )
	835
	836	!
	837	!-- Set flag when the time step becomes too small
	838	IF ( dt_1d < ( 0.00001 * dt_max_1d ) ) THEN
	839	stop_dt_1d = .TRUE.
	840	IF ( myid == 0 ) THEN
	841	PRINT*,'+++ timestep_1d: timestep has exceeded the lower limit'
	842	PRINT*,' dt_1d = ',dt_1d,' s simulation stopped!'
	843	ENDIF
	844	CALL local_stop
	845	ENDIF
	846
	847	IF ( timestep_scheme(1:4) == 'leap' ) THEN
	848
	849	!
	850	!-- The current time step will only be changed if the new time step exceeds
	851	!-- its previous value by 5 % or falls 2 % below. After a time step
	852	!-- reduction at least 30 iterations must be done with this value before a
	853	!-- new reduction will be allowed again.
	854	!-- The control parameters for application of Euler- or leap-frog schemes are
	855	!-- set accordingly.
	856	percent_change = dt_1d / old_dt_1d - 1.0
	857	IF ( percent_change > 0.05 .OR. percent_change < -0.02 ) THEN
	858
	859	!
	860	!-- Each time step increase is by at most 2 %
	861	IF ( percent_change > 0.0 .AND. simulated_time_1d /= 0.0 ) THEN
	862	dt_1d = 1.02 * old_dt_1d
	863	ENDIF
	864
	865	!
	866	!-- A more or less simple new time step value is obtained taking only the
	867	!-- first two significant digits
	868	div = 1000.0
	869	DO WHILE ( dt_1d < div )
	870	div = div / 10.0
	871	ENDDO
	872	dt_1d = NINT( dt_1d * 100.0 / div ) * div / 100.0
	873
	874	!
	875	!-- Now the time step can be changed.
	876	IF ( percent_change < 0.0 ) THEN
	877	!
	878	!-- Time step reduction
	879	old_dt_1d = dt_1d
	880	last_dt_change_1d = current_timestep_number_1d
	881	ELSE
	882	!
	883	!-- Time step will only be increased if at least 30 iterations have
	884	!-- been done since the previous time step change, and of course at
	885	!-- simulation start, respectively.
	886	IF ( current_timestep_number_1d >= last_dt_change_1d + 30 .OR. &
	887	simulated_time_1d == 0.0 ) THEN
	888	old_dt_1d = dt_1d
	889	last_dt_change_1d = current_timestep_number_1d
	890	ELSE
	891	dt_1d = old_dt_1d
	892	ENDIF
	893	ENDIF
	894	ELSE
	895	!
	896	!-- No time step change since the difference is too small
	897	dt_1d = old_dt_1d
	898	ENDIF
	899
	900	ELSE ! Runge-Kutta
	901
	902	!-- A more or less simple new time step value is obtained taking only the
	903	!-- first two significant digits
	904	div = 1000.0
	905	DO WHILE ( dt_1d < div )
	906	div = div / 10.0
	907	ENDDO
	908	dt_1d = NINT( dt_1d * 100.0 / div ) * div / 100.0
	909
	910	old_dt_1d = dt_1d
	911	last_dt_change_1d = current_timestep_number_1d
	912
	913	ENDIF
	914
	915	END SUBROUTINE timestep_1d
	916
	917
	918
	919	SUBROUTINE print_1d_model
	920
	921	!------------------------------------------------------------------------------!
	922	! Description:
	923	! ------------
	924	! List output of profiles from the 1D-model
	925	!------------------------------------------------------------------------------!
	926
	927	USE arrays_3d
	928	USE indices
	929	USE model_1d
	930	USE pegrid
	931	USE control_parameters
	932
	933	IMPLICIT NONE
	934
	935
	936	INTEGER :: k
	937
	938
	939	IF ( myid == 0 ) THEN
	940	!
	941	!-- Open list output file for profiles from the 1D-model
	942	CALL check_open( 17 )
	943
	944	!
	945	!-- Write Header
	946	WRITE ( 17, 100 ) TRIM( run_description_header ), &
	947	TRIM( simulated_time_chr )
	948	WRITE ( 17, 101 )
	949
	950	!
	951	!-- Write the values
	952	WRITE ( 17, 102 )
	953	WRITE ( 17, 101 )
	954	DO k = nzt+1, nzb, -1
	955	WRITE ( 17, 103) k, zu(k), u1d(k), v1d(k), pt_init(k), e1d(k), &
	956	rif1d(k), km1d(k), kh1d(k), l1d(k), zu(k), k
	957	ENDDO
	958	WRITE ( 17, 101 )
	959	WRITE ( 17, 102 )
	960	WRITE ( 17, 101 )
	961
	962	!
	963	!-- Write buffer contents to disc immediately
[82]	964	CALL local_flush( 17 )
[1]	965
	966	ENDIF
	967
	968	!
	969	!-- Formats
	970	100 FORMAT (//1X,A/1X,10('-')/' 1d-model profiles'/ &
	971	' Time: ',A)
	972	101 FORMAT (1X,79('-'))
	973	102 FORMAT (' k zu u v pt e rif Km Kh ', &
	974	'l zu k')
	975	103 FORMAT (1X,I4,1X,F7.1,1X,F6.2,1X,F6.2,1X,F6.2,1X,F6.2,1X,F5.2,1X,F5.2, &
	976	1X,F5.2,1X,F6.2,1X,F7.1,2X,I4)
	977
	978
	979	END SUBROUTINE print_1d_model

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